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Toxopneustes pileolus

August 25, 2023

Toxopneustes pileolus, commonly known as the flower urchin, is a widespread and commonly encountered species of sea urchin from the Indo-West Pacific. It is considered highly dangerous, as it is capable of delivering extremely painful and medically significant stings when touched. It inhabits coral reefs, seagrass beds, and rocky or sandy environments at depths of up to 90 m (295 ft). It feeds on algae, bryozoans, and organic detritus.

Flower urchin
Flower urchin from Okinawa, Japan
Scientific classification
Kingdom:
Animalia
Phylum:
Echinodermata
Class:
Echinoidea
Superorder:
Echinacea
Order:
Camarodonta
Infraorder:
Temnopleuridea
Family:
Toxopneustidae
Genus:
Toxopneustes
Species:
T. pileolus
Binomial name
Toxopneustes pileolus
(Lamarck, 1816)
  Estimated range
Synonyms[1]
  • Boletia heteropora
    L. Agassiz & Desor, 1846
  • Boletia pileolus
    (Lamarck, 1816)
  • Boletia polyzonalis
    (Lamarck, 1816)
  • Echinus pileolus
    Lamarck, 1816
  • Echinus polyzonalis
    Lamarck, 1816
  • Toxopneustes chloracanthus
    H.L. Clark, 1912

Its common name is derived from its numerous and distinctively flower-like pedicellariae, which are usually pinkish-white to yellowish-white in color with a central purple dot. It possesses short and blunt spines, though these are commonly hidden beneath the pedicellariae. The rigid "shell" (test) is a variegated deep red and gray in color, though in rare cases it may be greenish to light purple.

Taxonomy

Toxopneustes pileolus is one of four species belonging to the genus Toxopneustes. It belongs to the family Toxopneustidae in the order Camarodonta. It was originally described as Echinus pileolus by the French naturalist Jean-Baptiste Lamarck in 1816, in the second book of his Histoire naturelle des animaux sans vertèbres series. It was later used as the type species for the newly created genus Toxopneustes by the Swiss American biologist Louis Agassiz.[1]

The generic name Toxopneustes literally means "poison breath", derived from Greek τοξικόν [φάρμακον] (toksikón [phármakon], "arrow [poison]") and πνευστος (pneustos, "breath"). The specific name pileolus means "little cap" or "skullcap", from Latin pileus, a kind of brimless conical felt cap. In English, Toxopneustes pileolus is most widely known as the "flower urchin".[1] It is also sometimes known under various other common names, including "trumpet sea urchin",[2] "flower tip urchin",[3] "felt cap sea urchin",[4] and "poison claw sea urchin".[5] In the seashell collecting trade, Toxopneustes pileolus is known as the "mushroom urchin", due to their spineless empty shells (tests) resembling the caps of mushrooms.[6][7]

It is also known as tapumiti in Samoan;[8] tehe-tehe batu in Sinama and Tausug;[9] rappa-uni (ラッパウニ) or dokugaze (毒ガゼ) in Japanese;[1][10] and lǎbā dú jí hǎi dǎn (喇叭毒棘海膽) in Chinese.[11]

Description

See also: Sea urchin anatomy

Flower urchins are relatively large sea urchins. They can reach a maximum diameter of around 15 to 20 cm (6 to 8 in).[12][13]

 
Flower urchin from Tasitolu, East Timor (note the visible purple zigzag in one of the ambulacral segments)
 
Bottom (oral) surface of the flower urchin showing spines, tube feet, and the mouth with the chewing apparatus (Aristotle's lantern)

Like most echinoderms, the body of adult flower urchins is equally divided into identical segments around a central axis in multiples of five (pentaradial symmetry). The rigid "shell" (test) has five interambulacral segments separated from each other by five ambulacral segments, each of them are composed of smaller regularly interlocking plates. It is overlaid by a thin layer of skin in living individuals. The test is variegated in coloration, usually deep red and grey, though there are rare instances of green and pale purple.[14][15][16] Each ambulacral segment is ornamented by a large purple zigzag pattern running along its length.[14]

Two rows of tube feet emerge from the grooves on either side of each of the ambulacral segments (for a total of ten rows). The tube feet are individually composed of a thin muscular stalk (podia) tipped with a small suction cup (ampulla). The mouth is centrally located in the bottom (oral) surface of the test. It is surrounded by a ring of small plates overlaid by softer tissue known as the peristome. Embedded in the peristome are five calcareous "teeth" collectively known as Aristotle's lantern. These are used for grinding the flower urchin's food. The anus is situated on the upper (aboral) surface of the test, directly opposite the mouth. Like the mouth, it is surrounded by a ring of small plates known as the periproct. Surrounding the anal opening are five smaller holes (the genital pores) which are directly connected to the gonads inside the body cavity.[14][15]

The most conspicuous feature of flower urchins are their pedicellariae (stalked grasping appendages). Flower urchins possess four types of pedicellariae, distinguished by form and function, but only two are abundant. The first type are the ophicephalous pedicellariae. They resemble tube feet, except they end in three small claws (called valves) rather than suction cups. These are used to keep the body surface clear of algae, encrusting organisms, and unwanted debris.[16][17][18][19]

 
A - tube feet
B - pedicellariae (ophicephalous and globiferous)
C - spines
 
Illustration of a valve showing the sharp fang-like tip. Three of these form the claw-like ends of the flower urchin globiferous pedicellariae.[20]

The second type are the globiferous pedicellariae which superficially resemble flowers (hence its common name).[21] These are more specialized and are used for defense against predators and larger ectoparasites. Globiferous pedicellariae also end in a three-valved claw-like grasping appendage, like they do in ophicephalous pedicellariae, but they are much larger.[19][22] The valves are connected to each other by a distinctive circular membrane around 4 to 5 mm (0.16 to 0.20 in) in diameter. They are pinkish-white to yellowish-white in color with a central purple dot and a bright white rim.[14][19] Each valve ends in a sharp fang-like tip which is capable of penetrating human skin.[18][23][24] The base of the valves also house venom glands.[19][25] Some authors further subdivide globiferous pedicellariae into two subtypes based on size - the trumpet pedicellariae and the giant pedicellariae.[21] The other two types of pedicellariae - tridentate and triphyllous - are rare or restricted only to certain areas of the test.[16]

The relatively blunt spines are quite short and are usually hidden below the flower-like pedicellariae. They can vary from white, pink, yellow, light green, to purple in coloration with lighter-colored tips.[14][15]

Other members of the genus Toxopneustes are similar in appearance and can be mistaken for flower urchins. Toxopneustes roseus can be distinguished by the uniform coloration of their tests of pink, brown, or purple. It is also restricted to the East Pacific and thus aren't found together with flower urchins. Toxopneustes elegans, which is only found around Japan, can be distinguished by the presence of a distinctive dark stripe just below the tips of their spines. Toxopneustes maculatus is a very rare species known only from specimens from Réunion, Christmas Island, and the Palmyra Atoll. It can be distinguished by the bright violet coloration on the bottom and in a band around the middle of their tests.[15]

Distribution and habitat

Flower urchins are widespread and common in the tropical Indo-West Pacific.[12] They can be found north from Okinawa, Japan, to Tasmania, Australia in the south;[17][26] and west from the Red Sea and the East African coast,[1] to Raratonga in the Cook Islands in the east.[27] In Mexican waters, the Flower Urchin can be found in every waters of the Pacific with the exception that they are absent from Guerrero Negro (Bahia Tortugas), Baja California, northward along the central and northwest coasts of Baja.[28]

They are found among coral reefs, coral rubble, rocks, sand, and seagrass beds at depths of 0 to 90 m (0 to 295 ft) from the water's surface.[12][29] They may sometimes partially bury themselves on the substrate.[17]

Ecology and behavior

Diet

Flower urchins feed on algae, bryozoans, and organic detritus.[26][30]

Predators

Flower urchins have few predators.[17] They are known to be toxic to fish. One of the few organisms capable of consuming flower urchins with no apparent adverse effects is the predatory corallimorph Paracorynactis hoplites. However it is unknown if flower urchins are among its natural prey.[31]

Associated species

 
The zebra crab, Zebrida adamsii, is a parasite of flower urchins

The commensal alpheid shrimp Athanas areteformis, can sometimes be found living among the spines of flower urchins (as well as burrowing urchins and collector urchins).[32] The intestines of flower urchins can also serve as habitats for the commensal flatworm Syndesmis longicanalis.[33]

Flower urchins are also common hosts of the zebra crab, Zebrida adamsii. These tiny crabs are obligate symbionts of sea urchins. They cling to the spines on the outer surface of the sea urchin test using their highly specialized walking legs. Because their ability to walk on substrates like sand is impaired, zebra crabs spend their entire benthic life stage attached to sea urchins, switching between hosts only during the mating season. Usually only one zebra crab is attached to an individual sea urchin outside of the mating season, but larger sea urchins can be hosts to two (very rarely more). The area of the test they inhabit is characteristically smooth; completely devoid of spines, pedicellariae, tube feet, and even epidermis. It is unknown if they physically destroy and/or consume these appendages or if they use other stimuli to induce the host sea urchins to autotomize. Although previously considered harmless commensals, authors have since reclassified them as parasites. In addition to the visible external damage, a 1974 study also observed abnormal behavior and coloration among infected sea urchins. They also appear to be immune to the flower urchin's venom.[10][34][35]

Reproduction

Flower urchins are dioecious (having separate male and female individuals), but it is almost impossible to determine the sex of an individual by external characteristics alone. A possible method is by examining the external characteristics of the genital pores (gonopores). In males, they are generally short, cone-shaped, and extrude above the body surface; while in females they are usually sunken. However this is not reliable, as 15% of the cases can exhibit the opposite characteristics. All other external features, like shape and size of the tests or color of the spines are indistinguishable between the two sexes.[36] Flower urchins have a chromosome number of 2n = 42.[37]

Relatively little is known of the spawning behavior of flower urchins. Like other sea urchins, fertilization happens externally. Males and females release free-swimming gametes (eggs and sperm) directly into the water currents in mass spawning events.[38] In Okinawa, Japan, a 1994 study identified the spawning season of flower urchins as occurring in winter, at the same time as the closely related and sympatric Toxopneustes elegans. It also recorded possible natural hybrids resulting from instances where the eggs of Toxopneustes pileolus are fertilized by the sperm of Toxopneustes elegans.[39]

In Taiwan, a 2010 study observed flower urchins spawning in May on the years 2007 and 2009. They occurred on highly similar conditions: in the afternoon low tide of the spring tide immediately after a new moon. During the event, spawning individuals discard the debris that usually cover their bodies before releasing their gametes into the water.[38] Another study published in 2013 did not find any obvious correlation between lunar and tidal cycles to the mass spawning behavior of the flower urchin populations in southern Taiwan. It did note that the spawning patterns appeared to be non-random, with higher spawning rates on daytime on certain dates. However, the study was conducted within a span of only five months (from April to August 2010).[40]

"Covering" behavior

 
Flower urchin off the coast of Réunion exhibiting "covering" behavior

Flower urchins are among the numerous species of sea urchins known as "collector urchins", so named because they frequently cover the upper surfaces of their bodies with debris from their surroundings. This behavior is usually referred to as "covering" or "heaping".[29][34][41] Flower urchins are usually found almost completely covered in objects like dead coral fragments, shells, seaweed, and rocks.[17][42] These are held fast to their bodies using their tube feet and pedicellariae.[38]

The function of this behavior is not well understood. Some authors believe that the debris serve as ballast, preventing them from being swept away by wave surges when feeding;[38][43] while others believe that they may function as some sort of defense against predation.[34] A 2007 study has hypothesized that the behavior may serve as protection from UV radiation during daytime.[44]

Venom

Bioactive components

At least two active toxins have been purified from the pedicellarial venom of flower urchins in two studies.[45] The first was discovered in 1991 and named Contractin A. It was found to interfere with the transmission of signals at nerve endings as well as cause hemagglutination (clumping of the red blood cells).[46][47] When administered to guinea pigs, it resulted in contractions in the smooth muscles.[48]

The second, discovered in 1994, is a protein toxin named peditoxin. It is composed of the protein pedin and the active prosthetic group pedoxin. At low doses to mice, pedoxin was found to result in markedly lower body temperatures, muscle relaxation, sedation, and anesthetic coma. At higher doses it resulted in convulsions and death. Pedin itself is non-toxic, but it magnifies the effects of pedoxin. When combined into the holoprotein peditoxin, even low doses resulted in anaphylaxis-like shock and death.[49]

UT841, a possible third toxin isolated in 2001, has been shown to affect brain metabolism in chicks. However, the authors are unclear on whether UT841 may actually be the same compound as Contractin A, since both have the same molecular weight of 18,000 Da and an almost identical N-terminal sequence.[50]

In addition to these toxins, lectins have also been isolated from flower urchin venom. Among them is SUL-I, SUL-II, SUL-IA, and SUL-III (SUL stands for "sea urchin lectin"). These lectins may be valuable as research tools for investigating the functions of cell processes.[51]

 
Close up of a flower urchin. Note the tightly shut globiferous pedicellariae behind the extended tube feet.

Envenomation mechanism

Unlike most other venomous sea urchins, flower urchins and related toxopneustids do not deliver their venom through spines. Instead, the venom is administered through the flower-like globiferous pedicellariae.[18][23][24][25] If undisturbed, the tips of the globiferous pedicellariae are usually expanded into round cup-like shapes. They possess tiny sensors on their inside surfaces which can detect threats by touch and chemical stimuli. When agitated or brushed against by a potential threat, the pedicellariae will immediately snap shut and inject venom. The claws of the pedicellariae may also break off from their stalks and adhere to the point of contact, retaining the ability to continually inject venom for several hours.[4][34][52][53]

The potency of the pedicellarial venom is believed to be directly related to the size of the pedicellariae. Thus individuals with larger globiferous pedicellariae are considered to be more dangerous than individuals with more numerous but smaller globiferous pedicellariae.[21]

Effects on humans

In 1930, the Japanese marine biologist Tsutomu Fujiwara accidentally envenomated himself with seven or eight flower urchin pedicellariae while working in a fishing boat. He described his experience in a paper published in 1935:[34][52][53]

On June 26, 1930, while I was working on a fishing boat on the coast of Tsutajima in Saganoseki, I scooped up with my bare hand an individual of the sea-urchin which had been carried up by a diver with a fishing implement on the water surface from the sea-bottom about 20 fathoms in depth, and I transferred the sea-urchin into a small tank in the boat. At that time, 7 or 8 pedicellariae stubbornly attached themselves to a side of the middle finger of my right hand, detached from the stalk and remained on the skin of my finger.

Instantly, I felt a severe pain resembling that caused by the cnidoblast of Coelenterata, and I felt as if the toxin were beginning to move rapidly to the blood vessel from the stung area towards my heart. After a while, I experienced a faint giddiness, difficulty of respiration, paralysis of the lips, tongue and eyelids, relaxation of muscles in the limbs, was hardly able to speak or control my facial expression, and felt almost as if I were going to die. About 15 minutes afterwards, I felt that pains gradually diminish and after about an hour they disappeared completely. But the facial paralysis like that caused by cocainization continued for about six hours.

Tsutomu Fujiwara (1935). "On the poisonous pedicellaria of Toxopneustes pileolus (Lamarck)". Annotationes Zoologicae Japonenses. 15 (1): 62–68.

There have been reports of fatalities resulting from flower urchin envenomation.[54] One such report was the purported drowning of a pearl diver after being rendered unconscious from accidental contact with a flower urchin.[55][56][57] But it remains difficult to confirm if these incidents actually occurred since no documentation or details of the deaths have been uncovered so far.[55][58]

Nevertheless, flower urchins are still considered highly dangerous. The severe debilitating pain of the flower urchin sting compounded by muscular paralysis, breathing problems, numbness, and disorientation can result in accidental drowning among divers and swimmers.[4][18][59] The flower urchin was named the "most dangerous sea urchin" in the 2014 Guinness World Records.[60]

Edibility

 
Flower urchin from Longdong Bay, Taiwan, with some of the tube feet extending past the pedicellariae

Despite being venomous, flower urchins are sometimes harvested in East Asia, Southeast Asia, and the Pacific Islands for their edible gonads.[8][9][61][62] In the Sulu Archipelago of the Philippines and eastern Sabah, Malaysia, flower urchins are among the species of edible sea urchins used by the Sama-Bajau and Tausug people to make a traditional delicacy known as oko-oko or ketupat tehe tehe. This is prepared by degutting the test and then filling it with glutinous rice and coconut milk before boiling.[9]

Other uses

In Okinawa, fishermen observed numerous individuals of the predatory crown-of-thorns starfish (Acanthaster planci) gathering around the remains of the internal organs of flower urchins.[63] A follow-up study by Japanese researchers in 2001 confirmed that the viscera of flower urchins could indeed attract crown-of-thorns starfish in both aquarium and open sea experiments. The attractant compounds were isolated and identified as arachidonic acid and α-linolenic acid. The authors believe that this discovery may be used to augment population control measures of the crown-of-thorns starfish, which are highly destructive to coral reefs.[64]

References

  1. ^ a b c d e Andreas Kroh (2014). Kroh A, Mooi R (eds.). "Toxopneustes pileolus (Lamarck, 1816)". World Echinoidea Database. World Register of Marine Species. Retrieved November 22, 2014.
  2. ^ S. Amemiya (2002). "Developmental modes and rudiment formation in sea urchins". In Yukio Yokota; Valeria Matranga; Zuzana Smolenicka (eds.). The Sea Urchin: From Basic Biology to Aquaculture. CRC Press. p. 37. ISBN 9789058093790.
  3. ^ "Flower Urchin (Toxopneustes pileolus)". WHATSTHATFISH. 2014. Retrieved November 22, 2014.
  4. ^ a b c Gordon C. Cook; Alimuddin Zumla (2008). Manson's Tropical Diseases. Elsevier Health Sciences. p. 586. ISBN 9780702043321.
  5. ^ Rokus Groeneveld; Sanne Reijs (2014). "Echinoderms, sea urchins". Diverosa. Retrieved November 22, 2014.
  6. ^ Richard Howey (2005). "Calcareous Flowers: Tests and Cross-Sections of Sea Urchin Spines". Microscopy UK. Retrieved November 23, 2014.
  7. ^ . Paxton Gate. 2014. Archived from the original on November 29, 2014. Retrieved November 22, 2014.
  8. ^ a b Ministry of Natural Resources and Environment (2010). State of the Environment Report 2006 (PDF). Government of Samoa.
  9. ^ a b c Siti Akmar Khadijah Ab Rahim & Raymie Nurhasan (2012). "Edible sea urchin species in Sabah Waters" (PDF). Research Bulletin, Faculty of Resource Science and Technology. 1: 2–3.
  10. ^ a b Katsumi Suzuki; Masatsune Takeda (1974). "On a parthenopid crab, Zebrida adamsii on the sea urchins from Suruga Bay, with a special reference to their parasitic relations" (PDF). Bulletin of the National Science Museum. 17 (4): 286–296.
  11. ^ "Toxopneustes pileolus (Lamarck, 1816)". The Global Biodiversity Information Facility: GBIF Backbone Taxonomy. July 1, 2013. Retrieved November 22, 2014.
  12. ^ a b c M.L.D. Palomares; D. Pauly., eds. (2014). . SeaLifeBase. Archived from the original on November 29, 2014. Retrieved November 22, 2014.
  13. ^ "Flower Urchin (Toxopneustes pileolus)". Lord Howe Island Museum. Retrieved November 23, 2014.
  14. ^ a b c d e Frédéric Ducarme (2014). "Toxopneustes pileolus - Brief Summary". Encyclopedia of Life. Retrieved November 23, 2014.
  15. ^ a b c d Hubert Lyman Clark (1925). A Catalogue of the Recent Sea-Urchins (Echinoidea) in the Collection of the British Museum (Natural History). Oxford University Press. pp. 122–123.
  16. ^ a b c Alexander Agassiz; Hubert Lyman Clark (1912). "Hawaiian and Other Pacific Echini: The Pedinidae, Phymosomatidae, Stomopneustidae, Echinidae, Temnopleuridae, Strongylocentrotidae, and Echinometridae". Memoirs of the Museum of Comparative Zoölogy at Harvard College. 34 (4): 207–383. doi:10.5962/bhl.title.3820.
  17. ^ a b c d e Marine Animal Encyclopedia (2014). . Oceana. Archived from the original on November 29, 2014. Retrieved November 23, 2014.
  18. ^ a b c d "The Flower urchin has one hell of a nasty sting..." Destination-Scuba. Retrieved November 23, 2014.
  19. ^ a b c d Simon E. Coppard; Andreas Kroh; Andrew B. Smith (2010). "The evolution of pedicellariae in echinoids: an arms race against pests and parasites" (PDF). Acta Zoologica. 20 (2): 1–24. doi:10.1111/j.1463-6395.2010.00487.x.
  20. ^ Alexander Agassiz (1872). Revision of the Echini. Illustrated Catalogue of the Museum of Comparative Zoölogy at Harvard College. Cambridge University Press.
  21. ^ a b c H. Nakagawa; T. Hashimoto; H. Hayashi; M. Shinohara; K. Ohura; E. Tachikawa; T. Kashimoto (1996). Isolation of a novel lectin from the globiferous pedicellariae of the sea urchin Toxopneustes pileolus. pp. 213–223. doi:10.1007/978-1-4613-0361-9_14. ISBN 978-1-4613-8016-0. PMID 8726059. {{cite book}}: |journal= ignored (help)
  22. ^ Ole Theodor Jensen Mortensen (1903). The Danish Ingolf-Expedition Volume IV Part 1. H. Hagerup. p. 135–136.
  23. ^ a b Kozue Edo (2014). (PDF). Graduate School of Integrated Arts and Sciences, The University of Tokushima. Archived from the original (PDF) on 2014-11-29. Retrieved 2014-11-23.
  24. ^ a b Ronald L. Shimek (1997). . Reefs.org. Archived from the original on March 3, 2016. Retrieved November 23, 2014.
  25. ^ a b Pedro Nuño Ferreira. . Reefs Magazine. Archived from the original on November 29, 2014. Retrieved November 23, 2014.
  26. ^ a b Andrew Trevor-Jones (2008). "Toxopneustes pileolus". ATJ's Marine Aquarium Site. Retrieved November 23, 2014.
  27. ^ Gerald McCormack (2007). "Toxopneustes pileolus Flower Urchin". Cook Islands Biodiversity Database, Version 2007.2. Cook Islands Natural Heritage Trust. Retrieved November 23, 2014.
  28. ^ "Flower Sea Urchin". Mexico - Fish, Birds, Crabs, Marine Life, Shells and Terrestrial Life. 2018-03-30. Retrieved 2022-11-29.
  29. ^ a b M. de Beer (1990). "Distribution patterns of regular sea urchins (Echinodermata: Echinoidea) across the Spermonde Shelf, SW Sulawesi (Indonesia)". In C. De Ridder; P. Dubois; M.-C. Lahaye; M. Jangoux (eds.). Echinoderm Research. CRC Press. pp. 165–169. ISBN 9789061911418.
  30. ^ Bob Goemans (2012). "Toxopneustes pileolus". Saltcorner. Retrieved November 23, 2014.
  31. ^ Arthur R. Bos; Benjamin Mueller; Girley S. Gumanao (2011). "Feeding biology and symbiotic relationships of the corallimorpharian Paracorynactis hoplites (Anthozoa: Hexacorallia)" (PDF). The Raffles Bulletin of Zoology. 59 (2): 245–250.
  32. ^ Andreas Kroh (2014). Kroh A, Mooi R (eds.). "Echinometra mathaei (Blainville, 1825)". World Echinoidea Database. World Register of Marine Species. Retrieved November 22, 2014.
  33. ^ Jozef B. Moens; Els E. Martens; Ernest R. Schockaert (1994). "Syndesmis longicanalis sp. nov., an umagillid turbellarian (Platyhelminthes) from echinoids from the Kenyan coast" (PDF). Belgian Journal of Zoology. 124 (2): 105–114.
  34. ^ a b c d e Christopher Mah (February 4, 2014). "What we know about the world's most venomous sea urchin Toxopneustes fits in this blog post!". Echinoblog. Retrieved November 22, 2014.
  35. ^ Yasunobu Yanagisawa; Akira Hamaishi (1986). "Mate acquisition by a solitary crab Zebrida adamsii, a symbiont of the sea urchin". Journal of Ethology. 4 (2): 153–162. doi:10.1007/BF02348117. S2CID 22908082.
  36. ^ Yutaka Tahara; Minoru Okada; Naomasa Kobayashi (1958). "Secondary sexual characters in Japanese sea-urchins" (PDF). Publications of the Seto Marine Biological Laboratory. 7 (1): 165–172. doi:10.5134/174596.
  37. ^ T. Uehara; M. Shingaki; K. Taira; Y. Arakaki; H. Nakatomi (1991). "Chromosome studies in eleven Okinawan species of sea urchins, with special reference to four species of the Indo-Pacific Echinometra". In T. Yanagisawa; I. Yasumasu; C. Oguro; N. Suzuki; T. Motokawa (eds.). Biology of Echinodermata: Proceedings of the 7th International Echinoderm Conference, Japan (Atami) 9th - 14th September 1990. CRC Press. pp. 119–129. ISBN 9789054100102.
  38. ^ a b c d Andy Chen; Keryea Soong (2010). ""Uncovering" behavior at spawning of the trumpet sea urchin Toxopneustes pileolus" (PDF). Zoological Studies. 49 (1): 9.
  39. ^ K. Fukuchi; T. Uehara (1994). "Hybridization between species of sea urchins Toxopneustes elegans and Toxopneustes pileolus". In Bruno David; Alain Guille; Jean-Pierre Feral; Michel Roux (eds.). Echinoderms Through Time. CRC Press. p. 669. ISBN 9789054105145.
  40. ^ Shi-jie Lin (2013). Are there lunar patterns of gamete release in two sea urchins (Toxopneustes pileolus and Tripneustes gratilla)? (M.Sc.). Institute of Marine Biology, National Sun-Yat-sen University.
  41. ^ Yasunobu Yanagisawa (1972). "Preliminary observations on the so-called heaping behaviour in a sea urchin, Hemicentrotus pulcherrimus (A. Agassiz)" (PDF). Publications of the Seto Marine Biological Laboratory. 9 (6): 431–435.
  42. ^ Peter Frances; et al., eds. (2014). Ocean: The Definitive Visual Guide. Dorling Kindersley. p. 310. ISBN 9781465436207.
  43. ^ D. W. James (2000). "Diet, movement, and covering behavior of the sea urchin Toxopneustes roseus in rhodolith beds in the Gulf of California, México". Marine Biology. 137 (5–6): 913–923. doi:10.1007/s002270000423. S2CID 83820817.
  44. ^ Jessica E. Sigg; Karena M. Lloyd-Knight; Jean Geary Boal (2007). "UV radiation influences covering behaviour in the urchin Lytechinus variegatus". Journal of the Marine Biological Association of the United Kingdom. 87 (5): 1257–1261. doi:10.1017/s0025315407055865.
  45. ^ Yukio Yokota (2005). "Bioresources from Echinoderms". In Valeria Matranga (ed.). Echinodermata. Springer Science & Business Media. p. 257. ISBN 9783540244028.
  46. ^ Aaron Sewell (September 2007). . Advanced Aquarist Volume IV. CoralScience.org. Archived from the original on November 29, 2014. Retrieved November 23, 2014.
  47. ^ Randy Holmes-Farley (2008). "Sea Urchins: A Chemical Perspective". Reefkeeping. Retrieved November 23, 2014.
  48. ^ H. Nakagawa; A.T. Tu; A. Kimura (1991). "Purification and characterization of Contractin A from the pedicellarial venom of sea urchin, Toxopneustes pileolus". Archives of Biochemistry and Biophysics. 284 (2): 279–284. doi:10.1016/0003-9861(91)90296-u. PMID 1989511.
  49. ^ S. Kuwabara (1994). "Purification and properties of peditoxin and the structure of its prosthetic group, pedoxin, from the sea urchin Toxopneustes pileolus (Lamarck)". Journal of Biological Chemistry. 269 (43): 26734–26738. PMID 7929407.
  50. ^ Y. Zhang; J. Abe; A. Siddiq; H. Nakagawa; S. Honda; T. Wada; S. Ichida (2001). "UT841 purified from sea urchin (Toxopneustes pileolus) venom inhibits time-dependent 45Ca2+ uptake in crude synaptosome fraction from chick brain". Toxicon. 39 (8): 1223–1229. doi:10.1016/s0041-0101(00)00267-1. PMID 11306134.
  51. ^ Hitomi Sakai; Kozue Edo; Hideyuki Nakagawa; Mitsuko Shinohara; Rie Nishiitsutsuji; Kiyoshi Ohura (2013). "Isolation and partial characterization of a L-rhamnose-binding lectin from the globiferous pedicellariae of the toxopneustid sea urchin, Toxopneustes pileolus" (PDF). International Aquatic Research. 5 (12): 1–10.
  52. ^ a b Bruce W. Halstead (2013). "Venomous Echinoderms and Annelids". In Wolfgang Bücherl; Eleanor E. Buckley (eds.). Venomous Animals and Their Venoms: Volume III - Venomous Invertebrates. Academic Press, Inc. pp. 427–431. ISBN 9781483262895.
  53. ^ a b Tsutomu Fujiwara (1935). "On the poisonous pedicellaria of Toxopneustes pileolus (Lamarck)". Annotationes Zoologicae Japonenses. 15 (1): 62–68.
  54. ^ Frederick W. Oehme; Daniel E. Keyler (2007). "Plant and Animal Toxins". In A. Wallace Hayes (ed.). Principles and Methods of Toxicology, Fifth Edition. CRC Press. p. 1012. ISBN 9780849337789.
  55. ^ a b John A. Williamson; Joseph W. Burnett; Peter J. Fenner; Jacquie F. Rifkin (1996). Venomous and Poisonous Marine Animals: A Medical and Biological Handbook. UNSW Press. p. 322. ISBN 9780868402796.
  56. ^ Scott A. Gallagher. "Echinoderm Envenomation Clinical Presentation". Medscape. Retrieved November 22, 2014.
  57. ^ Elizabeth Mitchell; Ron Medzon (2005). Introduction to Emergency Medicine. Lippincott Williams & Wilkins. p. 513. ISBN 9780781732000.
  58. ^ World Health Organization (2003). "Dangerous Aquatic Organisms" (PDF). Guidelines for safe recreational water environments. Volume 1: Coastal and fresh waters. World Health Organization. p. 184. ISBN 978-9241545808.
  59. ^ William J Dahl; Peter Jebson; Dean S Louis (2010). "Sea urchin injuries to the hand: a case report and review of the literature". Iowa Orthopaedic Journal. 30: 153–156. PMC 2958287. PMID 21045988.
  60. ^ Craig Glenday, ed. (2014). Guinness World Records 2014. Bantam. p. 30. ISBN 9780553390551.
  61. ^ Takasi Tokioka (1963). "Supposed effects of the cold weather of the winter 1962–63 upon the intertidal fauna in the vicinity of Seto" (PDF). Publications of the Seto Marine Biological Laboratory. 11 (2): 415–424. doi:10.5134/175332.
  62. ^ Shyh-Min Chao; Bang-Chin Chen (2012). "High density of flower urchin, Toxopneustes pileolus, in Houbihu Lagoon, Southern Taiwan". Platax. 9: 77–81. doi:10.29926/PLATAX.201212.0006.
  63. ^ Daisuke Uemura (2010). "Exploratory research on bioactive natural products with a focus on biological phenomena". Proceedings of the Japan Academy, Series B: Physical and Biological Sciences. 86 (3): 190–201. doi:10.2183/pjab.86.190. PMC 3417845. PMID 20228620.
  64. ^ Toshiaki Teruya; Kiyotake Suenaga; Tomoyuki Koyama; Yoshikatsu Nakano; Daisuke Uemura (2001). "Arachidonic acid and α-linolenic acid, feeding attractants for the crown-of-thorns sea star Acanthaster planci, from the sea urchin Toxopneustes pileolus". Journal of Experimental Marine Biology and Ecology. 266 (2): 123–134. doi:10.1016/S0022-0981(01)00337-9.

External links

 
Wikimedia Commons has media related to Toxopneustes pileolus.
  • Christopher Mah (February 4, 2014). "What we know about the world's most venomous sea urchin Toxopneustes fits in this blog post!". Echinoblog.
  • Video of a live flower urchin in its natural habitat (YouTube)
  • Video of a live captive flower urchin (YouTube)
  • Video of a flower urchin with a zebra crab (YouTube)
  • Photos of Toxopneustes pileolus on Sealife Collection

August 25, 2023
toxopneustes, pileolus, commonly, known, flower, urchin, widespread, commonly, encountered, species, urchin, from, indo, west, pacific, considered, highly, dangerous, capable, delivering, extremely, painful, medically, significant, stings, when, touched, inhab. Toxopneustes pileolus commonly known as the flower urchin is a widespread and commonly encountered species of sea urchin from the Indo West Pacific It is considered highly dangerous as it is capable of delivering extremely painful and medically significant stings when touched It inhabits coral reefs seagrass beds and rocky or sandy environments at depths of up to 90 m 295 ft It feeds on algae bryozoans and organic detritus Flower urchinFlower urchin from Okinawa JapanScientific classificationKingdom AnimaliaPhylum EchinodermataClass EchinoideaSuperorder EchinaceaOrder CamarodontaInfraorder TemnopleurideaFamily ToxopneustidaeGenus ToxopneustesSpecies T pileolusBinomial nameToxopneustes pileolus Lamarck 1816 Estimated rangeSynonyms 1 Boletia heteroporaL Agassiz amp Desor 1846 Boletia pileolus Lamarck 1816 Boletia polyzonalis Lamarck 1816 Echinus pileolusLamarck 1816 Echinus polyzonalisLamarck 1816 Toxopneustes chloracanthusH L Clark 1912Its common name is derived from its numerous and distinctively flower like pedicellariae which are usually pinkish white to yellowish white in color with a central purple dot It possesses short and blunt spines though these are commonly hidden beneath the pedicellariae The rigid shell test is a variegated deep red and gray in color though in rare cases it may be greenish to light purple Contents 1 Taxonomy 2 Description 3 Distribution and habitat 4 Ecology and behavior 4 1 Diet 4 2 Predators 4 3 Associated species 4 4 Reproduction 4 5 Covering behavior 5 Venom 5 1 Bioactive components 5 2 Envenomation mechanism 5 3 Effects on humans 6 Edibility 7 Other uses 8 References 9 External linksTaxonomy EditToxopneustes pileolus is one of four species belonging to the genus Toxopneustes It belongs to the family Toxopneustidae in the order Camarodonta It was originally described as Echinus pileolus by the French naturalist Jean Baptiste Lamarck in 1816 in the second book of his Histoire naturelle des animaux sans vertebres series It was later used as the type species for the newly created genus Toxopneustes by the Swiss American biologist Louis Agassiz 1 The generic name Toxopneustes literally means poison breath derived from Greek to3ikon farmakon toksikon pharmakon arrow poison and pneystos pneustos breath The specific name pileolus means little cap or skullcap from Latin pileus a kind of brimless conical felt cap In English Toxopneustes pileolus is most widely known as the flower urchin 1 It is also sometimes known under various other common names including trumpet sea urchin 2 flower tip urchin 3 felt cap sea urchin 4 and poison claw sea urchin 5 In the seashell collecting trade Toxopneustes pileolus is known as the mushroom urchin due to their spineless empty shells tests resembling the caps of mushrooms 6 7 It is also known as tapumiti in Samoan 8 tehe tehe batu in Sinama and Tausug 9 rappa uni ラッパウニ or dokugaze 毒ガゼ in Japanese 1 10 and lǎba du ji hǎi dǎn 喇叭毒棘海膽 in Chinese 11 Description EditSee also Sea urchin anatomy Flower urchins are relatively large sea urchins They can reach a maximum diameter of around 15 to 20 cm 6 to 8 in 12 13 Flower urchin from Tasitolu East Timor note the visible purple zigzag in one of the ambulacral segments Bottom oral surface of the flower urchin showing spines tube feet and the mouth with the chewing apparatus Aristotle s lantern Like most echinoderms the body of adult flower urchins is equally divided into identical segments around a central axis in multiples of five pentaradial symmetry The rigid shell test has five interambulacral segments separated from each other by five ambulacral segments each of them are composed of smaller regularly interlocking plates It is overlaid by a thin layer of skin in living individuals The test is variegated in coloration usually deep red and grey though there are rare instances of green and pale purple 14 15 16 Each ambulacral segment is ornamented by a large purple zigzag pattern running along its length 14 Two rows of tube feet emerge from the grooves on either side of each of the ambulacral segments for a total of ten rows The tube feet are individually composed of a thin muscular stalk podia tipped with a small suction cup ampulla The mouth is centrally located in the bottom oral surface of the test It is surrounded by a ring of small plates overlaid by softer tissue known as the peristome Embedded in the peristome are five calcareous teeth collectively known as Aristotle s lantern These are used for grinding the flower urchin s food The anus is situated on the upper aboral surface of the test directly opposite the mouth Like the mouth it is surrounded by a ring of small plates known as the periproct Surrounding the anal opening are five smaller holes the genital pores which are directly connected to the gonads inside the body cavity 14 15 The most conspicuous feature of flower urchins are their pedicellariae stalked grasping appendages Flower urchins possess four types of pedicellariae distinguished by form and function but only two are abundant The first type are the ophicephalous pedicellariae They resemble tube feet except they end in three small claws called valves rather than suction cups These are used to keep the body surface clear of algae encrusting organisms and unwanted debris 16 17 18 19 A tube feetB pedicellariae ophicephalous and globiferous C spines Illustration of a valve showing the sharp fang like tip Three of these form the claw like ends of the flower urchin globiferous pedicellariae 20 The second type are the globiferous pedicellariae which superficially resemble flowers hence its common name 21 These are more specialized and are used for defense against predators and larger ectoparasites Globiferous pedicellariae also end in a three valved claw like grasping appendage like they do in ophicephalous pedicellariae but they are much larger 19 22 The valves are connected to each other by a distinctive circular membrane around 4 to 5 mm 0 16 to 0 20 in in diameter They are pinkish white to yellowish white in color with a central purple dot and a bright white rim 14 19 Each valve ends in a sharp fang like tip which is capable of penetrating human skin 18 23 24 The base of the valves also house venom glands 19 25 Some authors further subdivide globiferous pedicellariae into two subtypes based on size the trumpet pedicellariae and the giant pedicellariae 21 The other two types of pedicellariae tridentate and triphyllous are rare or restricted only to certain areas of the test 16 The relatively blunt spines are quite short and are usually hidden below the flower like pedicellariae They can vary from white pink yellow light green to purple in coloration with lighter colored tips 14 15 Other members of the genus Toxopneustes are similar in appearance and can be mistaken for flower urchins Toxopneustes roseus can be distinguished by the uniform coloration of their tests of pink brown or purple It is also restricted to the East Pacific and thus aren t found together with flower urchins Toxopneustes elegans which is only found around Japan can be distinguished by the presence of a distinctive dark stripe just below the tips of their spines Toxopneustes maculatus is a very rare species known only from specimens from Reunion Christmas Island and the Palmyra Atoll It can be distinguished by the bright violet coloration on the bottom and in a band around the middle of their tests 15 Distribution and habitat EditFlower urchins are widespread and common in the tropical Indo West Pacific 12 They can be found north from Okinawa Japan to Tasmania Australia in the south 17 26 and west from the Red Sea and the East African coast 1 to Raratonga in the Cook Islands in the east 27 In Mexican waters the Flower Urchin can be found in every waters of the Pacific with the exception that they are absent from Guerrero Negro Bahia Tortugas Baja California northward along the central and northwest coasts of Baja 28 They are found among coral reefs coral rubble rocks sand and seagrass beds at depths of 0 to 90 m 0 to 295 ft from the water s surface 12 29 They may sometimes partially bury themselves on the substrate 17 Ecology and behavior EditDiet Edit Flower urchins feed on algae bryozoans and organic detritus 26 30 Predators Edit Flower urchins have few predators 17 They are known to be toxic to fish One of the few organisms capable of consuming flower urchins with no apparent adverse effects is the predatory corallimorph Paracorynactis hoplites However it is unknown if flower urchins are among its natural prey 31 Associated species Edit The zebra crab Zebrida adamsii is a parasite of flower urchinsThe commensal alpheid shrimp Athanas areteformis can sometimes be found living among the spines of flower urchins as well as burrowing urchins and collector urchins 32 The intestines of flower urchins can also serve as habitats for the commensal flatworm Syndesmis longicanalis 33 Flower urchins are also common hosts of the zebra crab Zebrida adamsii These tiny crabs are obligate symbionts of sea urchins They cling to the spines on the outer surface of the sea urchin test using their highly specialized walking legs Because their ability to walk on substrates like sand is impaired zebra crabs spend their entire benthic life stage attached to sea urchins switching between hosts only during the mating season Usually only one zebra crab is attached to an individual sea urchin outside of the mating season but larger sea urchins can be hosts to two very rarely more The area of the test they inhabit is characteristically smooth completely devoid of spines pedicellariae tube feet and even epidermis It is unknown if they physically destroy and or consume these appendages or if they use other stimuli to induce the host sea urchins to autotomize Although previously considered harmless commensals authors have since reclassified them as parasites In addition to the visible external damage a 1974 study also observed abnormal behavior and coloration among infected sea urchins They also appear to be immune to the flower urchin s venom 10 34 35 Reproduction Edit Flower urchins are dioecious having separate male and female individuals but it is almost impossible to determine the sex of an individual by external characteristics alone A possible method is by examining the external characteristics of the genital pores gonopores In males they are generally short cone shaped and extrude above the body surface while in females they are usually sunken However this is not reliable as 15 of the cases can exhibit the opposite characteristics All other external features like shape and size of the tests or color of the spines are indistinguishable between the two sexes 36 Flower urchins have a chromosome number of 2n 42 37 Relatively little is known of the spawning behavior of flower urchins Like other sea urchins fertilization happens externally Males and females release free swimming gametes eggs and sperm directly into the water currents in mass spawning events 38 In Okinawa Japan a 1994 study identified the spawning season of flower urchins as occurring in winter at the same time as the closely related and sympatric Toxopneustes elegans It also recorded possible natural hybrids resulting from instances where the eggs of Toxopneustes pileolus are fertilized by the sperm of Toxopneustes elegans 39 In Taiwan a 2010 study observed flower urchins spawning in May on the years 2007 and 2009 They occurred on highly similar conditions in the afternoon low tide of the spring tide immediately after a new moon During the event spawning individuals discard the debris that usually cover their bodies before releasing their gametes into the water 38 Another study published in 2013 did not find any obvious correlation between lunar and tidal cycles to the mass spawning behavior of the flower urchin populations in southern Taiwan It did note that the spawning patterns appeared to be non random with higher spawning rates on daytime on certain dates However the study was conducted within a span of only five months from April to August 2010 40 Covering behavior Edit Flower urchin off the coast of Reunion exhibiting covering behaviorFlower urchins are among the numerous species of sea urchins known as collector urchins so named because they frequently cover the upper surfaces of their bodies with debris from their surroundings This behavior is usually referred to as covering or heaping 29 34 41 Flower urchins are usually found almost completely covered in objects like dead coral fragments shells seaweed and rocks 17 42 These are held fast to their bodies using their tube feet and pedicellariae 38 The function of this behavior is not well understood Some authors believe that the debris serve as ballast preventing them from being swept away by wave surges when feeding 38 43 while others believe that they may function as some sort of defense against predation 34 A 2007 study has hypothesized that the behavior may serve as protection from UV radiation during daytime 44 Venom EditBioactive components Edit At least two active toxins have been purified from the pedicellarial venom of flower urchins in two studies 45 The first was discovered in 1991 and named Contractin A It was found to interfere with the transmission of signals at nerve endings as well as cause hemagglutination clumping of the red blood cells 46 47 When administered to guinea pigs it resulted in contractions in the smooth muscles 48 The second discovered in 1994 is a protein toxin named peditoxin It is composed of the protein pedin and the active prosthetic group pedoxin At low doses to mice pedoxin was found to result in markedly lower body temperatures muscle relaxation sedation and anesthetic coma At higher doses it resulted in convulsions and death Pedin itself is non toxic but it magnifies the effects of pedoxin When combined into the holoprotein peditoxin even low doses resulted in anaphylaxis like shock and death 49 UT841 a possible third toxin isolated in 2001 has been shown to affect brain metabolism in chicks However the authors are unclear on whether UT841 may actually be the same compound as Contractin A since both have the same molecular weight of 18 000 Da and an almost identical N terminal sequence 50 In addition to these toxins lectins have also been isolated from flower urchin venom Among them is SUL I SUL II SUL IA and SUL III SUL stands for sea urchin lectin These lectins may be valuable as research tools for investigating the functions of cell processes 51 Close up of a flower urchin Note the tightly shut globiferous pedicellariae behind the extended tube feet Envenomation mechanism Edit Unlike most other venomous sea urchins flower urchins and related toxopneustids do not deliver their venom through spines Instead the venom is administered through the flower like globiferous pedicellariae 18 23 24 25 If undisturbed the tips of the globiferous pedicellariae are usually expanded into round cup like shapes They possess tiny sensors on their inside surfaces which can detect threats by touch and chemical stimuli When agitated or brushed against by a potential threat the pedicellariae will immediately snap shut and inject venom The claws of the pedicellariae may also break off from their stalks and adhere to the point of contact retaining the ability to continually inject venom for several hours 4 34 52 53 The potency of the pedicellarial venom is believed to be directly related to the size of the pedicellariae Thus individuals with larger globiferous pedicellariae are considered to be more dangerous than individuals with more numerous but smaller globiferous pedicellariae 21 Effects on humans Edit In 1930 the Japanese marine biologist Tsutomu Fujiwara accidentally envenomated himself with seven or eight flower urchin pedicellariae while working in a fishing boat He described his experience in a paper published in 1935 34 52 53 On June 26 1930 while I was working on a fishing boat on the coast of Tsutajima in Saganoseki I scooped up with my bare hand an individual of the sea urchin which had been carried up by a diver with a fishing implement on the water surface from the sea bottom about 20 fathoms in depth and I transferred the sea urchin into a small tank in the boat At that time 7 or 8 pedicellariae stubbornly attached themselves to a side of the middle finger of my right hand detached from the stalk and remained on the skin of my finger Instantly I felt a severe pain resembling that caused by the cnidoblast of Coelenterata and I felt as if the toxin were beginning to move rapidly to the blood vessel from the stung area towards my heart After a while I experienced a faint giddiness difficulty of respiration paralysis of the lips tongue and eyelids relaxation of muscles in the limbs was hardly able to speak or control my facial expression and felt almost as if I were going to die About 15 minutes afterwards I felt that pains gradually diminish and after about an hour they disappeared completely But the facial paralysis like that caused by cocainization continued for about six hours Tsutomu Fujiwara 1935 On the poisonous pedicellaria of Toxopneustes pileolus Lamarck Annotationes Zoologicae Japonenses 15 1 62 68 There have been reports of fatalities resulting from flower urchin envenomation 54 One such report was the purported drowning of a pearl diver after being rendered unconscious from accidental contact with a flower urchin 55 56 57 But it remains difficult to confirm if these incidents actually occurred since no documentation or details of the deaths have been uncovered so far 55 58 Nevertheless flower urchins are still considered highly dangerous The severe debilitating pain of the flower urchin sting compounded by muscular paralysis breathing problems numbness and disorientation can result in accidental drowning among divers and swimmers 4 18 59 The flower urchin was named the most dangerous sea urchin in the 2014 Guinness World Records 60 Edibility Edit Flower urchin from Longdong Bay Taiwan with some of the tube feet extending past the pedicellariaeDespite being venomous flower urchins are sometimes harvested in East Asia Southeast Asia and the Pacific Islands for their edible gonads 8 9 61 62 In the Sulu Archipelago of the Philippines and eastern Sabah Malaysia flower urchins are among the species of edible sea urchins used by the Sama Bajau and Tausug people to make a traditional delicacy known as oko oko or ketupat tehe tehe This is prepared by degutting the test and then filling it with glutinous rice and coconut milk before boiling 9 Other uses EditIn Okinawa fishermen observed numerous individuals of the predatory crown of thorns starfish Acanthaster planci gathering around the remains of the internal organs of flower urchins 63 A follow up study by Japanese researchers in 2001 confirmed that the viscera of flower urchins could indeed attract crown of thorns starfish in both aquarium and open sea experiments The attractant compounds were isolated and identified as arachidonic acid and a linolenic acid The authors believe that this discovery may be used to augment population control measures of the crown of thorns starfish which are highly destructive to coral reefs 64 References Edit a b c d e Andreas Kroh 2014 Kroh A Mooi R eds Toxopneustes pileolus Lamarck 1816 World Echinoidea Database World Register of Marine Species Retrieved November 22 2014 S Amemiya 2002 Developmental modes and rudiment formation in sea urchins In Yukio Yokota Valeria Matranga Zuzana Smolenicka eds The Sea Urchin From Basic Biology to Aquaculture CRC Press p 37 ISBN 9789058093790 Flower Urchin Toxopneustes pileolus WHATSTHATFISH 2014 Retrieved November 22 2014 a b c Gordon C Cook Alimuddin Zumla 2008 Manson s Tropical Diseases Elsevier Health Sciences p 586 ISBN 9780702043321 Rokus Groeneveld Sanne Reijs 2014 Echinoderms sea urchins Diverosa Retrieved November 22 2014 Richard Howey 2005 Calcareous Flowers Tests and Cross Sections of Sea Urchin Spines Microscopy UK Retrieved November 23 2014 Sea Urchin Mushroom Paxton Gate 2014 Archived from the original on November 29 2014 Retrieved November 22 2014 a b Ministry of Natural Resources and Environment 2010 State of the Environment Report 2006 PDF Government of Samoa a b c Siti Akmar Khadijah Ab Rahim amp Raymie Nurhasan 2012 Edible sea urchin species in Sabah Waters PDF Research Bulletin Faculty of Resource Science and Technology 1 2 3 a b Katsumi Suzuki Masatsune Takeda 1974 On a parthenopid crab Zebrida adamsii on the sea urchins from Suruga Bay with a special reference to their parasitic relations PDF Bulletin of the National Science Museum 17 4 286 296 Toxopneustes pileolus Lamarck 1816 The Global Biodiversity Information Facility GBIF Backbone Taxonomy July 1 2013 Retrieved November 22 2014 a b c M L D Palomares D Pauly eds 2014 Toxopneustes pileolus Lamarck 1816 SeaLifeBase Archived from the original on November 29 2014 Retrieved November 22 2014 Flower Urchin Toxopneustes pileolus Lord Howe Island Museum Retrieved November 23 2014 a b c d e Frederic Ducarme 2014 Toxopneustes pileolus Brief Summary Encyclopedia of Life Retrieved November 23 2014 a b c d Hubert Lyman Clark 1925 A Catalogue of the Recent Sea Urchins Echinoidea in the Collection of the British Museum Natural History Oxford University Press pp 122 123 a b c Alexander Agassiz Hubert Lyman Clark 1912 Hawaiian and Other Pacific Echini The Pedinidae Phymosomatidae Stomopneustidae Echinidae Temnopleuridae Strongylocentrotidae and Echinometridae Memoirs of the Museum of Comparative Zoology at Harvard College 34 4 207 383 doi 10 5962 bhl title 3820 a b c d e Marine Animal Encyclopedia 2014 Flower Urchin Toxopneustes pileolus Oceana Archived from the original on November 29 2014 Retrieved November 23 2014 a b c d The Flower urchin has one hell of a nasty sting Destination Scuba Retrieved November 23 2014 a b c d Simon E Coppard Andreas Kroh Andrew B Smith 2010 The evolution of pedicellariae in echinoids an arms race against pests and parasites PDF Acta Zoologica 20 2 1 24 doi 10 1111 j 1463 6395 2010 00487 x Alexander Agassiz 1872 Revision of the Echini Illustrated Catalogue of the Museum of Comparative Zoology at Harvard College Cambridge University Press a b c H Nakagawa T Hashimoto H Hayashi M Shinohara K Ohura E Tachikawa T Kashimoto 1996 Isolation of a novel lectin from the globiferous pedicellariae of the sea urchinToxopneustes pileolus pp 213 223 doi 10 1007 978 1 4613 0361 9 14 ISBN 978 1 4613 8016 0 PMID 8726059 a href Template Cite book html title Template Cite book cite book a journal ignored help Ole Theodor Jensen Mortensen 1903 The Danish Ingolf Expedition Volume IV Part 1 H Hagerup p 135 136 a b Kozue Edo 2014 Study on a pedicellarial venom lectin from the sea urchinToxopneustes pileolus in the coast of Tokushima Prefecture Japan PDF Graduate School of Integrated Arts and Sciences The University of Tokushima Archived from the original PDF on 2014 11 29 Retrieved 2014 11 23 a b Ronald L Shimek 1997 There is No Reason to Be Spineless Reefs org Archived from the original on March 3 2016 Retrieved November 23 2014 a b Pedro Nuno Ferreira When Beauty Turns to Beast And Hell Breaks Loose in the Reef System Reefs Magazine Archived from the original on November 29 2014 Retrieved November 23 2014 a b Andrew Trevor Jones 2008 Toxopneustes pileolus ATJ s Marine Aquarium Site Retrieved November 23 2014 Gerald McCormack 2007 Toxopneustes pileolus Flower Urchin Cook Islands Biodiversity Database Version 2007 2 Cook Islands Natural Heritage Trust Retrieved November 23 2014 Flower Sea Urchin Mexico Fish Birds Crabs Marine Life Shells and Terrestrial Life 2018 03 30 Retrieved 2022 11 29 a b M de Beer 1990 Distribution patterns of regular sea urchins Echinodermata Echinoidea across the Spermonde Shelf SW Sulawesi Indonesia In C De Ridder P Dubois M C Lahaye M Jangoux eds Echinoderm Research CRC Press pp 165 169 ISBN 9789061911418 Bob Goemans 2012 Toxopneustes pileolus Saltcorner Retrieved November 23 2014 Arthur R Bos Benjamin Mueller Girley S Gumanao 2011 Feeding biology and symbiotic relationships of the corallimorpharian Paracorynactis hoplites Anthozoa Hexacorallia PDF The Raffles Bulletin of Zoology 59 2 245 250 Andreas Kroh 2014 Kroh A Mooi R eds Echinometra mathaei Blainville 1825 World Echinoidea Database World Register of Marine Species Retrieved November 22 2014 Jozef B Moens Els E Martens Ernest R Schockaert 1994 Syndesmis longicanalis sp nov an umagillid turbellarian Platyhelminthes from echinoids from the Kenyan coast PDF Belgian Journal of Zoology 124 2 105 114 a b c d e Christopher Mah February 4 2014 What we know about the world s most venomous sea urchin Toxopneustes fits in this blog post Echinoblog Retrieved November 22 2014 Yasunobu Yanagisawa Akira Hamaishi 1986 Mate acquisition by a solitary crab Zebrida adamsii a symbiont of the sea urchin Journal of Ethology 4 2 153 162 doi 10 1007 BF02348117 S2CID 22908082 Yutaka Tahara Minoru Okada Naomasa Kobayashi 1958 Secondary sexual characters in Japanese sea urchins PDF Publications of the Seto Marine Biological Laboratory 7 1 165 172 doi 10 5134 174596 T Uehara M Shingaki K Taira Y Arakaki H Nakatomi 1991 Chromosome studies in eleven Okinawan species of sea urchins with special reference to four species of the Indo Pacific Echinometra In T Yanagisawa I Yasumasu C Oguro N Suzuki T Motokawa eds Biology of Echinodermata Proceedings of the 7th International Echinoderm Conference Japan Atami 9th 14th September 1990 CRC Press pp 119 129 ISBN 9789054100102 a b c d Andy Chen Keryea Soong 2010 Uncovering behavior at spawning of the trumpet sea urchin Toxopneustes pileolus PDF Zoological Studies 49 1 9 K Fukuchi T Uehara 1994 Hybridization between species of sea urchins Toxopneustes elegans and Toxopneustes pileolus In Bruno David Alain Guille Jean Pierre Feral Michel Roux eds Echinoderms Through Time CRC Press p 669 ISBN 9789054105145 Shi jie Lin 2013 Are there lunar patterns of gamete release in two sea urchins Toxopneustes pileolusandTripneustes gratilla M Sc Institute of Marine Biology National Sun Yat sen University Yasunobu Yanagisawa 1972 Preliminary observations on the so called heaping behaviour in a sea urchin Hemicentrotus pulcherrimus A Agassiz PDF Publications of the Seto Marine Biological Laboratory 9 6 431 435 Peter Frances et al eds 2014 Ocean The Definitive Visual Guide Dorling Kindersley p 310 ISBN 9781465436207 D W James 2000 Diet movement and covering behavior of the sea urchin Toxopneustes roseus in rhodolith beds in the Gulf of California Mexico Marine Biology 137 5 6 913 923 doi 10 1007 s002270000423 S2CID 83820817 Jessica E Sigg Karena M Lloyd Knight Jean Geary Boal 2007 UV radiation influences covering behaviour in the urchin Lytechinus variegatus Journal of the Marine Biological Association of the United Kingdom 87 5 1257 1261 doi 10 1017 s0025315407055865 Yukio Yokota 2005 Bioresources from Echinoderms In Valeria Matranga ed Echinodermata Springer Science amp Business Media p 257 ISBN 9783540244028 Aaron Sewell September 2007 Feature Article Toxins Venoms and Inhibitory Chemicals in Marine Organisms Advanced Aquarist Volume IV CoralScience org Archived from the original on November 29 2014 Retrieved November 23 2014 Randy Holmes Farley 2008 Sea Urchins A Chemical Perspective Reefkeeping Retrieved November 23 2014 H Nakagawa A T Tu A Kimura 1991 Purification and characterization of Contractin A from the pedicellarial venom of sea urchin Toxopneustes pileolus Archives of Biochemistry and Biophysics 284 2 279 284 doi 10 1016 0003 9861 91 90296 u PMID 1989511 S Kuwabara 1994 Purification and properties of peditoxin and the structure of its prosthetic group pedoxin from the sea urchin Toxopneustes pileolus Lamarck Journal of Biological Chemistry 269 43 26734 26738 PMID 7929407 Y Zhang J Abe A Siddiq H Nakagawa S Honda T Wada S Ichida 2001 UT841 purified from sea urchin Toxopneustes pileolus venom inhibits time dependent 45Ca2 uptake in crude synaptosome fraction from chick brain Toxicon 39 8 1223 1229 doi 10 1016 s0041 0101 00 00267 1 PMID 11306134 Hitomi Sakai Kozue Edo Hideyuki Nakagawa Mitsuko Shinohara Rie Nishiitsutsuji Kiyoshi Ohura 2013 Isolation and partial characterization of a L rhamnose binding lectin from the globiferous pedicellariae of the toxopneustid sea urchin Toxopneustes pileolus PDF International Aquatic Research 5 12 1 10 a b Bruce W Halstead 2013 Venomous Echinoderms and Annelids In Wolfgang Bucherl Eleanor E Buckley eds Venomous Animals and Their Venoms Volume III Venomous Invertebrates Academic Press Inc pp 427 431 ISBN 9781483262895 a b Tsutomu Fujiwara 1935 On the poisonous pedicellaria of Toxopneustes pileolus Lamarck Annotationes Zoologicae Japonenses 15 1 62 68 Frederick W Oehme Daniel E Keyler 2007 Plant and Animal Toxins In A Wallace Hayes ed Principles and Methods of Toxicology Fifth Edition CRC Press p 1012 ISBN 9780849337789 a b John A Williamson Joseph W Burnett Peter J Fenner Jacquie F Rifkin 1996 Venomous and Poisonous Marine Animals A Medical and Biological Handbook UNSW Press p 322 ISBN 9780868402796 Scott A Gallagher Echinoderm Envenomation Clinical Presentation Medscape Retrieved November 22 2014 Elizabeth Mitchell Ron Medzon 2005 Introduction to Emergency Medicine Lippincott Williams amp Wilkins p 513 ISBN 9780781732000 World Health Organization 2003 Dangerous Aquatic Organisms PDF Guidelines for safe recreational water environments Volume 1 Coastal and fresh waters World Health Organization p 184 ISBN 978 9241545808 William J Dahl Peter Jebson Dean S Louis 2010 Sea urchin injuries to the hand a case report and review of the literature Iowa Orthopaedic Journal 30 153 156 PMC 2958287 PMID 21045988 Craig Glenday ed 2014 Guinness World Records 2014 Bantam p 30 ISBN 9780553390551 Takasi Tokioka 1963 Supposed effects of the cold weather of the winter 1962 63 upon the intertidal fauna in the vicinity of Seto PDF Publications of the Seto Marine Biological Laboratory 11 2 415 424 doi 10 5134 175332 Shyh Min Chao Bang Chin Chen 2012 High density of flower urchin Toxopneustes pileolus in Houbihu Lagoon Southern Taiwan Platax 9 77 81 doi 10 29926 PLATAX 201212 0006 Daisuke Uemura 2010 Exploratory research on bioactive natural products with a focus on biological phenomena Proceedings of the Japan Academy Series B Physical and Biological Sciences 86 3 190 201 doi 10 2183 pjab 86 190 PMC 3417845 PMID 20228620 Toshiaki Teruya Kiyotake Suenaga Tomoyuki Koyama Yoshikatsu Nakano Daisuke Uemura 2001 Arachidonic acid and a linolenic acid feeding attractants for the crown of thorns sea star Acanthaster planci from the sea urchin Toxopneustes pileolus Journal of Experimental Marine Biology and Ecology 266 2 123 134 doi 10 1016 S0022 0981 01 00337 9 External links Edit Wikimedia Commons has media related to Toxopneustes pileolus Christopher Mah February 4 2014 What we know about the world s most venomous sea urchin Toxopneustes fits in this blog post Echinoblog Video of a live flower urchin in its natural habitat YouTube Video of a live captive flower urchin YouTube Video of a flower urchin with a zebra crab YouTube Photos of Toxopneustes pileolus on Sealife Collection Retrieved from https en wikipedia org w index php title Toxopneustes pileolus amp oldid 1170981348, wikipedia, wiki, book, books, library,

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